////////////////////////////////////////////////////////////////
//
//          AMaZE demosaic algorithm
// (Aliasing Minimization and Zipper Elimination)
//
//  copyright (c) 2008-2010  Emil Martinec <ejmartin@uchicago.edu>
//  optimized for speed by Ingo Weyrich
//
// incorporating ideas of Luis Sanz Rodrigues and Paul Lee
//
// code dated: May 27, 2010
// latest modification: Ingo Weyrich, January 25, 2016
//
//  amaze.cc is free software: you can redistribute it and/or modify
//  it under the terms of the GNU General Public License as published by
//  the Free Software Foundation, either version 3 of the License, or
//  (at your option) any later version.
//
//  This program is distributed in the hope that it will be useful,
//  but WITHOUT ANY WARRANTY; without even the implied warranty of
//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
//  GNU General Public License for more details.
//
//  You should have received a copy of the GNU General Public License
//  along with this program.  If not, see <http://www.gnu.org/licenses/>.
//
////////////////////////////////////////////////////////////////

#include <algorithm>
#include <array>
#include <cstring>
#include <memory>

#include "bayerhelper.h"
#include "librtprocess.h"
#include "rt_math.h"
#include "sleef.c"
#include "opthelper.h"
#include "median.h"
#include "StopWatch.h"

using namespace librtprocess;

rpError amaze_demosaic(int raw_width, int raw_height, int winx, int winy, int winw, int winh, const float * const *rawData, float **red, float **green, float **blue, const unsigned cfarray[2][2], const std::function<bool(double)> &setProgCancel, double initGain, int border, float inputScale, float outputScale, size_t chunkSize, bool measure)
{
    BENCHFUN
    std::unique_ptr<StopWatch> stop;

    if (measure) {
        std::cout << "Demosaicing " << winw << "x" << winh << " image using AMaZE with " << chunkSize << " Tiles per Thread" << std::endl;
        stop.reset(new StopWatch("amaze demosaic"));
    }

    if (!validateBayerCfa(3, cfarray)) {
        return RP_WRONG_CFA;
    }
    rpError rc = RP_NO_ERROR;

    double progress = 0.0;
    setProgCancel(progress);

    const int width = winw, height = winh;
    const float clip_pt = 1.0 / initGain;
    const float clip_pt8 = 0.8 / initGain;

// this allows to pass AMAZETS to the code. On some machines larger AMAZETS is faster
// If AMAZETS is undefined it will be set to 160, which is the fastest on modern x86/64 machines
#ifndef AMAZETS
#define AMAZETS 160
#endif
    // Tile size; the image is processed in square tiles to lower memory requirements and facilitate multi-threading
    // We assure that Tile size is a multiple of 32 in the range [96;992]
    constexpr int ts = (AMAZETS & 992) < 96 ? 96 : (AMAZETS & 992);
    constexpr int tsh = ts / 2; // half of Tile size
 
    //offset of R pixel within a Bayer quartet
    int ex, ey;

    //determine GRBG coset; (ey,ex) is the offset of the R subarray
    if (fc(cfarray, 0, 0) == 1) { //first pixel is G
        if (fc(cfarray, 0, 1) == 0) {
            ey = 0;
            ex = 1;
        } else {
            ey = 1;
            ex = 0;
        }
    } else {//first pixel is R or B
        if (fc(cfarray, 0, 0) == 0) {
            ey = 0;
            ex = 0;
        } else {
            ey = 1;
            ex = 1;
        }
    }

    //shifts of pointer value to access pixels in vertical and diagonal directions
    constexpr int v1 = ts, v2 = 2 * ts, v3 = 3 * ts, p1 = -ts + 1, p2 = -2 * ts + 2, p3 = -3 * ts + 3, m1 = ts + 1, m2 = 2 * ts + 2, m3 = 3 * ts + 3;

    //tolerance to avoid dividing by zero
    constexpr float eps = 1e-5, epssq = 1e-10;       //tolerance to avoid dividing by zero

    //adaptive ratios threshold
    constexpr float arthresh = 0.75;

    //gaussian on 5x5 quincunx, sigma=1.2
    constexpr float gaussodd[4] = {0.14659727707323927f, 0.103592713382435f, 0.0732036125103057f, 0.0365543548389495f};
    //nyquist texture test threshold
    constexpr float nyqthresh = 0.5;
    //gaussian on 5x5, sigma=1.2, multiplied with nyqthresh to save some time later in loop
    // Is this really sigma=1.2????, seems more like sigma = 1.672
    constexpr float gaussgrad[6] = {nyqthresh * 0.07384411893421103f, nyqthresh * 0.06207511968171489f, nyqthresh * 0.0521818194747806f,
                                    nyqthresh * 0.03687419286733595f, nyqthresh * 0.03099732204057846f, nyqthresh * 0.018413194161458882f
                                   };
    //gaussian on 5x5 alt quincunx, sigma=1.5
    constexpr float gausseven[2] = {0.13719494435797422f, 0.05640252782101291f};
    //gaussian on quincunx grid
    constexpr float gquinc[4] = {0.169917f, 0.108947f, 0.069855f, 0.0287182f};

    typedef struct {
        float h;
        float v;
    } s_hv;

#ifdef _OPENMP
    #pragma omp parallel
#endif
    {
        int progresscounter = 0;

        constexpr int cldf = 2; // factor to multiply cache line distance. 1 = 64 bytes, 2 = 128 bytes ...
        // assign working space
        char *buffer = (char *) calloc(14 * sizeof(float) * ts * ts + sizeof(char) * ts * tsh + 18 * cldf * 64 + 63, 1);
#ifdef _OPENMP
        #pragma omp critical
#endif
        {
            if (!buffer) {
                rc = RP_MEMORY_ERROR;
            }
        }
#ifdef _OPENMP
        #pragma omp barrier
#endif
        if (!rc) {
            // aligned to 64 byte boundary
            float *data = (float*)((uintptr_t(buffer) + uintptr_t(63)) / 64 * 64);

            // green values
            float *rgbgreen         = data;
            // sum of square of horizontal gradient and square of vertical gradient
            float *delhvsqsum       = rgbgreen + ts * ts + cldf * 16;
            // gradient based directional weights for interpolation
            float *dirwts0          = delhvsqsum + ts * ts + cldf * 16;
            float *dirwts1          = dirwts0 + ts * ts + cldf * 16;
            // vertically interpolated colour differences G-R, G-B
            float *vcd              = dirwts1 + ts * ts + cldf * 16;
            // horizontally interpolated colour differences
            float *hcd              = vcd + ts * ts + cldf * 16;
            // alternative vertical interpolation
            float *vcdalt           = hcd + ts * ts + cldf * 16;
            // alternative horizontal interpolation
            float *hcdalt           = vcdalt + ts * ts + cldf * 16;
            // square of average colour difference
            float *cddiffsq         = hcdalt + ts * ts + cldf * 16;
            // weight to give horizontal vs vertical interpolation
            float *hvwt             = cddiffsq + ts * ts + 2 * cldf * 16;
            // final interpolated colour difference
            float (*Dgrb)[ts * tsh] = (float (*)[ts * tsh]) vcdalt; // there is no overlap in buffer usage => share
            // gradient in plus (NE/SW) direction
            float *delp             = cddiffsq; // there is no overlap in buffer usage => share
            // gradient in minus (NW/SE) direction
            float *delm             = delp + ts * tsh + cldf * 16;
            // diagonal interpolation of R+B
            float *rbint            = delm; // there is no overlap in buffer usage => share
            // difference between up/down interpolations of G
            float *dgintv           = hvwt + ts * tsh + cldf * 16;
            // difference between left/right interpolations of G
            float *dginth           = dgintv + ts * ts + cldf * 16;
            // horizontal and vertical curvature of interpolated G (used to refine interpolation in Nyquist texture regions)
            s_hv  *Dgrb2            = (s_hv  (*)) dgintv; // there is no overlap in buffer usage => share
            // square of diagonal colour differences
            float *Dgrbsq1m         = dginth + ts * ts + cldf * 16;
            float *Dgrbsq1p         = Dgrbsq1m + ts * tsh + cldf * 16;
            // tile raw data
            float *cfa              = Dgrbsq1p + ts * tsh + cldf * 16;
            // relative weight for combining plus and minus diagonal interpolations
            float *pmwt             = delhvsqsum;  // there is no overlap in buffer usage => share
            // interpolated colour difference R-B in minus and plus direction
            float *rbm              = vcd;  // there is no overlap in buffer usage => share
            float *rbp              = rbm + ts * tsh + cldf * 16;
            // nyquist texture flags 1=nyquist, 0=not nyquist
            unsigned char *nyquist  = (unsigned char (*)) (cfa + ts * ts + cldf * 16);            // 1
            unsigned char *nyquist2 = (unsigned char (*)) cddiffsq;
            float *nyqutest = (float(*)) (nyquist + sizeof(unsigned char) * ts * tsh + cldf * 64);                // 1

            // Main algorithm: Tile loop
            // use collapse(2) to collapse the 2 loops to one large loop, so there is better scaling
#ifdef _OPENMP
            #pragma omp for schedule(dynamic, chunkSize) collapse(2) nowait
#endif

            for (int top = winy - 16; top < winy + height; top += ts - 32) {
                for (int left = winx - 16; left < winx + width; left += ts - 32) {
                    memset(&nyquist[3 * tsh], 0, sizeof(unsigned char) * (ts - 6) * tsh);
                    //location of tile bottom edge
                    int bottom = min(top + ts, winy + height + 16);
                    //location of tile right edge
                    int right  = min(left + ts, winx + width + 16);
                    //tile width  (=ts except for right edge of image)
                    int rr1 = bottom - top;
                    //tile height (=ts except for bottom edge of image)
                    int cc1 = right - left;
                    // bookkeeping for borders
                    // min and max row/column in the tile
                    int rrmin = top < 0 ? 16 : 0;
                    int ccmin = left < 0 ? 16 : 0;
                    //int rrmax = bottom > (winy + height) ? winy + height - top : rr1;
                    int rrmax = bottom > (raw_height) ? winy + height - top : rr1;
                    //int ccmax = right > (winx + width) ? winx + width - left : cc1;
                    int ccmax = right > (raw_width) ? winx + width - left : cc1;

                    // rgb from input CFA data
                    // rgb values should be floating point number between 0 and 1
                    // after white balance multipliers are applied
                    // a 16 pixel border is added to each side of the image

                    // begin of tile initialization
#ifdef __SSE2__
                    vfloat cinScalev = F2V( inputScale );

                    //fill upper border
                    if (rrmin > 0) {
                        for (int rr = 0; rr < 16; rr++) {
                            int row = 32 - rr + top;

                            for (int cc = ccmin; cc < ccmax; cc += 4) {
                                int indx1 = rr * ts + cc;
                                vfloat tempv = LVFU(rawData[row][cc + left]) / cinScalev;
                                STVF(cfa[indx1], tempv);
                                STVF(rgbgreen[indx1], tempv );
                            }
                        }
                    }

                    // fill inner part
                    for (int rr = rrmin; rr < rrmax; rr++) {
                        int row = rr + top;
                        int cc = ccmin;
                        for (; cc < ccmax - 3; cc += 4) {
                            int indx1 = rr * ts + cc;
                            vfloat tempv = LVFU(rawData[row][cc + left]) / cinScalev;
                            STVF(cfa[indx1], tempv );
                            STVF(rgbgreen[indx1], tempv );
                        }
                        for (; cc < ccmax; ++cc) {
                            int indx1 = rr * ts + cc;
                            float temp = rawData[row][cc + left] / inputScale;
                            cfa[indx1] = temp;
                            rgbgreen[indx1] = temp;
                        }
                    }

                    //fill lower border
                    if (rrmax < rr1) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = ccmin; cc < ccmax; cc += 4) {
                                int indx1 = (rrmax + rr) * ts + cc;
                                vfloat tempv = LVFU(rawData[(winy + height - rr - 2)][left + cc]) / cinScalev;
                                STVF(cfa[indx1], tempv );
                                STVF(rgbgreen[indx1], tempv );
                            }
                    }

#else

                    //fill upper border
                    if (rrmin > 0) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = ccmin, row = 32 - rr + top; cc < ccmax; cc++) {
                                cfa[rr * ts + cc] = (rawData[row][cc + left]) / inputScale;
                                rgbgreen[rr * ts + cc] = cfa[rr * ts + cc];
                            }
                    }

                    // fill inner part
                    for (int rr = rrmin; rr < rrmax; rr++) {
                        int row = rr + top;

                        for (int cc = ccmin; cc < ccmax; cc++) {
                            int indx1 = rr * ts + cc;
                            cfa[indx1] = (rawData[row][cc + left]) / inputScale;
                            rgbgreen[indx1] = cfa[indx1];
                        }
                    }

                    //fill lower border
                    if (rrmax < rr1) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = ccmin; cc < ccmax; cc++) {
                                cfa[(rrmax + rr)*ts + cc] = (rawData[(winy + height - rr - 2)][left + cc]) / inputScale;
                                rgbgreen[(rrmax + rr)*ts + cc] = cfa[(rrmax + rr) * ts + cc];
                            }
                    }

#endif

                    //fill left border
                    if (ccmin > 0) {
                        for (int rr = rrmin; rr < rrmax; rr++)
                            for (int cc = 0, row = rr + top; cc < 16; cc++) {
                                cfa[rr * ts + cc] = (rawData[row][32 - cc + left]) / inputScale;
                                rgbgreen[rr * ts + cc] = cfa[rr * ts + cc];
                            }
                    }

                    //fill right border
                    if (ccmax < cc1) {
                        for (int rr = rrmin; rr < rrmax; rr++)
                            for (int cc = 0; cc < 16; cc++) {
                                cfa[rr * ts + ccmax + cc] = (rawData[(top + rr)][(winx + width - cc - 2)]) / inputScale;
                                rgbgreen[rr * ts + ccmax + cc] = cfa[rr * ts + ccmax + cc];
                            }
                    }

                    //also, fill the image corners
                    if (rrmin > 0 && ccmin > 0) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = 0; cc < 16; cc++) {
                                cfa[(rr)*ts + cc] = (rawData[winy + 32 - rr][winx + 32 - cc]) / inputScale;
                                rgbgreen[(rr)*ts + cc] = cfa[(rr) * ts + cc];
                            }
                    }

                    if (rrmax < rr1 && ccmax < cc1) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = 0; cc < 16; cc++) {
                                cfa[(rrmax + rr)*ts + ccmax + cc] = (rawData[(winy + height - rr - 2)][(winx + width - cc - 2)]) / inputScale;
                                rgbgreen[(rrmax + rr)*ts + ccmax + cc] = cfa[(rrmax + rr) * ts + ccmax + cc];
                            }
                    }

                    if (rrmin > 0 && ccmax < cc1) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = 0; cc < 16; cc++) {
                                cfa[(rr)*ts + ccmax + cc] = (rawData[(winy + 32 - rr)][(winx + width - cc - 2)]) / inputScale;
                                rgbgreen[(rr)*ts + ccmax + cc] = cfa[(rr) * ts + ccmax + cc];
                            }
                    }

                    if (rrmax < rr1 && ccmin > 0) {
                        for (int rr = 0; rr < 16; rr++)
                            for (int cc = 0; cc < 16; cc++) {
                                cfa[(rrmax + rr)*ts + cc] = (rawData[(winy + height - rr - 2)][(winx + 32 - cc)]) / inputScale;
                                rgbgreen[(rrmax + rr)*ts + cc] = cfa[(rrmax + rr) * ts + cc];
                            }
                    }

                    // end of tile initialization

                    // horizontal and vertical gradients
#ifdef __SSE2__
                    vfloat epsv = F2V( eps );

                    for (int rr = 2; rr < rr1 - 2; rr++) {
                        for (int indx = rr * ts; indx < rr * ts + cc1; indx += 4) {
                            vfloat delhv = vabsf( LVFU( cfa[indx + 1] ) -  LVFU( cfa[indx - 1] ) );
                            vfloat delvv = vabsf( LVF( cfa[indx + v1] ) -  LVF( cfa[indx - v1] ) );
                            STVF(dirwts1[indx], epsv + vabsf( LVFU( cfa[indx + 2] ) - LVF( cfa[indx] )) + vabsf( LVF( cfa[indx] ) - LVFU( cfa[indx - 2] )) + delhv );
                            STVF(dirwts0[indx], epsv + vabsf( LVF( cfa[indx + v2] ) - LVF( cfa[indx] )) + vabsf( LVF( cfa[indx] ) - LVF( cfa[indx - v2] )) + delvv );
                            STVF(delhvsqsum[indx], SQRV(delhv) + SQRV(delvv));
                        }
                    }

#else

                    for (int rr = 2; rr < rr1 - 2; rr++)
                        for (int cc = 2, indx = (rr) * ts + cc; cc < cc1 - 2; cc++, indx++) {
                            float delh = fabsf(cfa[indx + 1] - cfa[indx - 1]);
                            float delv = fabsf(cfa[indx + v1] - cfa[indx - v1]);
                            dirwts0[indx] = eps + fabsf(cfa[indx + v2] - cfa[indx]) + fabsf(cfa[indx] - cfa[indx - v2]) + delv;
                            dirwts1[indx] = eps + fabsf(cfa[indx + 2] - cfa[indx]) + fabsf(cfa[indx] - cfa[indx - 2]) + delh;
                            delhvsqsum[indx] = SQR(delh) + SQR(delv);
                        }

#endif

                    //interpolate vertical and horizontal colour differences
#ifdef __SSE2__
                    vfloat sgnv;

                    if( !(fc(cfarray, 4, 4) & 1) ) {
                        sgnv = _mm_set_ps( 1.f, -1.f, 1.f, -1.f );
                    } else {
                        sgnv = _mm_set_ps( -1.f, 1.f, -1.f, 1.f );
                    }

                    vfloat zd5v = F2V( 0.5f );
                    vfloat onev = F2V( 1.f );
                    vfloat arthreshv = F2V( arthresh );
                    vfloat clip_pt8v = F2V( clip_pt8 );

                    for (int rr = 4; rr < rr1 - 4; rr++) {
                        sgnv = -sgnv;

                        for (int indx = rr * ts + 4; indx < rr * ts + cc1 - 7; indx += 4) {
                            //colour ratios in each cardinal direction
                            vfloat cfav = LVF(cfa[indx]);
                            vfloat cruv = LVF(cfa[indx - v1]) * (LVF(dirwts0[indx - v2]) + LVF(dirwts0[indx])) / (LVF(dirwts0[indx - v2]) * (epsv + cfav) + LVF(dirwts0[indx]) * (epsv + LVF(cfa[indx - v2])));
                            vfloat crdv = LVF(cfa[indx + v1]) * (LVF(dirwts0[indx + v2]) + LVF(dirwts0[indx])) / (LVF(dirwts0[indx + v2]) * (epsv + cfav) + LVF(dirwts0[indx]) * (epsv + LVF(cfa[indx + v2])));
                            vfloat crlv = LVFU(cfa[indx - 1]) * (LVFU(dirwts1[indx - 2]) + LVF(dirwts1[indx])) / (LVFU(dirwts1[indx - 2]) * (epsv + cfav) + LVF(dirwts1[indx]) * (epsv + LVFU(cfa[indx - 2])));
                            vfloat crrv = LVFU(cfa[indx + 1]) * (LVFU(dirwts1[indx + 2]) + LVF(dirwts1[indx])) / (LVFU(dirwts1[indx + 2]) * (epsv + cfav) + LVF(dirwts1[indx]) * (epsv + LVFU(cfa[indx + 2])));

                            //G interpolated in vert/hor directions using Hamilton-Adams method
                            vfloat guhav = LVF(cfa[indx - v1]) + zd5v * (cfav - LVF(cfa[indx - v2]));
                            vfloat gdhav = LVF(cfa[indx + v1]) + zd5v * (cfav - LVF(cfa[indx + v2]));
                            vfloat glhav = LVFU(cfa[indx - 1]) + zd5v * (cfav - LVFU(cfa[indx - 2]));
                            vfloat grhav = LVFU(cfa[indx + 1]) + zd5v * (cfav - LVFU(cfa[indx + 2]));

                            //G interpolated in vert/hor directions using adaptive ratios
                            vfloat guarv = vself(vmaskf_lt(vabsf(onev - cruv), arthreshv), cfav * cruv, guhav);
                            vfloat gdarv = vself(vmaskf_lt(vabsf(onev - crdv), arthreshv), cfav * crdv, gdhav);
                            vfloat glarv = vself(vmaskf_lt(vabsf(onev - crlv), arthreshv), cfav * crlv, glhav);
                            vfloat grarv = vself(vmaskf_lt(vabsf(onev - crrv), arthreshv), cfav * crrv, grhav);

                            //adaptive weights for vertical/horizontal directions
                            vfloat hwtv = LVFU(dirwts1[indx - 1]) / (LVFU(dirwts1[indx - 1]) + LVFU(dirwts1[indx + 1]));
                            vfloat vwtv = LVF(dirwts0[indx - v1]) / (LVF(dirwts0[indx + v1]) + LVF(dirwts0[indx - v1]));

                            //interpolated G via adaptive weights of cardinal evaluations
                            vfloat Ginthhav = vintpf(hwtv, grhav, glhav);
                            vfloat Gintvhav = vintpf(vwtv, gdhav, guhav);

                            //interpolated colour differences
                            vfloat hcdaltv = sgnv * (Ginthhav - cfav);
                            vfloat vcdaltv = sgnv * (Gintvhav - cfav);
                            STVF(hcdalt[indx], hcdaltv);
                            STVF(vcdalt[indx], vcdaltv);

                            vmask clipmask = vorm( vorm( vmaskf_gt( cfav, clip_pt8v ), vmaskf_gt( Gintvhav, clip_pt8v ) ), vmaskf_gt( Ginthhav, clip_pt8v ));
                            guarv = vself( clipmask, guhav, guarv);
                            gdarv = vself( clipmask, gdhav, gdarv);
                            glarv = vself( clipmask, glhav, glarv);
                            grarv = vself( clipmask, grhav, grarv);

                            //use HA if highlights are (nearly) clipped
                            STVF(vcd[indx], vself( clipmask, vcdaltv, sgnv * (vintpf(vwtv, gdarv, guarv) - cfav)));
                            STVF(hcd[indx], vself( clipmask, hcdaltv, sgnv * (vintpf(hwtv, grarv, glarv) - cfav)));

                            //differences of interpolations in opposite directions
                            STVF(dgintv[indx], vminf(SQRV(guhav - gdhav), SQRV(guarv - gdarv)));
                            STVF(dginth[indx], vminf(SQRV(glhav - grhav), SQRV(glarv - grarv)));
                        }
                    }

#else

                    for (int rr = 4; rr < rr1 - 4; rr++) {
                        bool fcswitch = fc(cfarray, rr, 4) & 1;

                        for (int cc = 4, indx = rr * ts + cc; cc < cc1 - 4; cc++, indx++) {

                            //colour ratios in each cardinal direction
                            float cru = cfa[indx - v1] * (dirwts0[indx - v2] + dirwts0[indx]) / (dirwts0[indx - v2] * (eps + cfa[indx]) + dirwts0[indx] * (eps + cfa[indx - v2]));
                            float crd = cfa[indx + v1] * (dirwts0[indx + v2] + dirwts0[indx]) / (dirwts0[indx + v2] * (eps + cfa[indx]) + dirwts0[indx] * (eps + cfa[indx + v2]));
                            float crl = cfa[indx - 1] * (dirwts1[indx - 2] + dirwts1[indx]) / (dirwts1[indx - 2] * (eps + cfa[indx]) + dirwts1[indx] * (eps + cfa[indx - 2]));
                            float crr = cfa[indx + 1] * (dirwts1[indx + 2] + dirwts1[indx]) / (dirwts1[indx + 2] * (eps + cfa[indx]) + dirwts1[indx] * (eps + cfa[indx + 2]));

                            //G interpolated in vert/hor directions using Hamilton-Adams method
                            float guha = cfa[indx - v1] + xdiv2f(cfa[indx] - cfa[indx - v2]);
                            float gdha = cfa[indx + v1] + xdiv2f(cfa[indx] - cfa[indx + v2]);
                            float glha = cfa[indx - 1] + xdiv2f(cfa[indx] - cfa[indx - 2]);
                            float grha = cfa[indx + 1] + xdiv2f(cfa[indx] - cfa[indx + 2]);

                            //G interpolated in vert/hor directions using adaptive ratios
                            float guar, gdar, glar, grar;

                            if (fabsf(1.f - cru) < arthresh) {
                                guar = cfa[indx] * cru;
                            } else {
                                guar = guha;
                            }

                            if (fabsf(1.f - crd) < arthresh) {
                                gdar = cfa[indx] * crd;
                            } else {
                                gdar = gdha;
                            }

                            if (fabsf(1.f - crl) < arthresh) {
                                glar = cfa[indx] * crl;
                            } else {
                                glar = glha;
                            }

                            if (fabsf(1.f - crr) < arthresh) {
                                grar = cfa[indx] * crr;
                            } else {
                                grar = grha;
                            }

                            //adaptive weights for vertical/horizontal directions
                            float hwt = dirwts1[indx - 1] / (dirwts1[indx - 1] + dirwts1[indx + 1]);
                            float vwt = dirwts0[indx - v1] / (dirwts0[indx + v1] + dirwts0[indx - v1]);

                            //interpolated G via adaptive weights of cardinal evaluations
                            float Gintvha = vwt * gdha + (1.f - vwt) * guha;
                            float Ginthha = hwt * grha + (1.f - hwt) * glha;

                            //interpolated colour differences
                            if (fcswitch) {
                                vcd[indx] = cfa[indx] - (vwt * gdar + (1.f - vwt) * guar);
                                hcd[indx] = cfa[indx] - (hwt * grar + (1.f - hwt) * glar);
                                vcdalt[indx] = cfa[indx] - Gintvha;
                                hcdalt[indx] = cfa[indx] - Ginthha;
                            } else {
                                //interpolated colour differences
                                vcd[indx] = (vwt * gdar + (1.f - vwt) * guar) - cfa[indx];
                                hcd[indx] = (hwt * grar + (1.f - hwt) * glar) - cfa[indx];
                                vcdalt[indx] = Gintvha - cfa[indx];
                                hcdalt[indx] = Ginthha - cfa[indx];
                            }

                            fcswitch = !fcswitch;

                            if (cfa[indx] > clip_pt8 || Gintvha > clip_pt8 || Ginthha > clip_pt8) {
                                //use HA if highlights are (nearly) clipped
                                guar = guha;
                                gdar = gdha;
                                glar = glha;
                                grar = grha;
                                vcd[indx] = vcdalt[indx];
                                hcd[indx] = hcdalt[indx];
                            }

                            //differences of interpolations in opposite directions
                            dgintv[indx] = min(SQR(guha - gdha), SQR(guar - gdar));
                            dginth[indx] = min(SQR(glha - grha), SQR(glar - grar));

                        }
                    }

#endif



#ifdef __SSE2__
                    vfloat  clip_ptv = F2V( clip_pt );
                    vfloat  sgn3v;

                    if( !(fc(cfarray, 4, 4) & 1) ) {
                        sgnv = _mm_set_ps( 1.f, -1.f, 1.f, -1.f );
                    } else {
                        sgnv = _mm_set_ps( -1.f, 1.f, -1.f, 1.f );
                    }

                    sgn3v = sgnv + sgnv + sgnv;

                    for (int rr = 4; rr < rr1 - 4; rr++) {
                        vfloat nsgnv = sgnv;
                        sgnv = -sgnv;
                        sgn3v = -sgn3v;

                        for (int indx = rr * ts + 4; indx < rr * ts + cc1 - 4; indx += 4) {
                            vfloat hcdv = LVF( hcd[indx] );
                            vfloat hcdvarv = SQRV(LVFU(hcd[indx - 2]) - hcdv) + SQRV(LVFU(hcd[indx - 2]) - LVFU(hcd[indx + 2])) + SQRV(hcdv - LVFU(hcd[indx + 2]));
                            vfloat hcdaltv = LVF( hcdalt[indx] );
                            vfloat hcdaltvarv = SQRV(LVFU(hcdalt[indx - 2]) - hcdaltv) + SQRV(LVFU(hcdalt[indx - 2]) - LVFU(hcdalt[indx + 2])) + SQRV(hcdaltv - LVFU(hcdalt[indx + 2]));
                            vfloat vcdv = LVF( vcd[indx] );
                            vfloat vcdvarv = SQRV(LVF(vcd[indx - v2]) - vcdv) + SQRV(LVF(vcd[indx - v2]) - LVF(vcd[indx + v2])) + SQRV(vcdv - LVF(vcd[indx + v2]));
                            vfloat vcdaltv = LVF( vcdalt[indx] );
                            vfloat vcdaltvarv = SQRV(LVF(vcdalt[indx - v2]) - vcdaltv) + SQRV(LVF(vcdalt[indx - v2]) - LVF(vcdalt[indx + v2])) + SQRV(vcdaltv - LVF(vcdalt[indx + v2]));

                            //choose the smallest variance; this yields a smoother interpolation
                            hcdv = vself( vmaskf_lt( hcdaltvarv, hcdvarv ), hcdaltv, hcdv);
                            vcdv = vself( vmaskf_lt( vcdaltvarv, vcdvarv ), vcdaltv, vcdv);

                            //bound the interpolation in regions of high saturation
                            //vertical and horizontal G interpolations
                            vfloat Ginthv = sgnv * hcdv + LVF( cfa[indx] );
                            vfloat temp2v = sgn3v * hcdv;
                            vfloat hwtv = onev + temp2v / ( epsv + Ginthv + LVF( cfa[indx]));
                            vmask hcdmask = vmaskf_gt( nsgnv * hcdv, ZEROV );
                            vfloat hcdoldv = hcdv;
                            vfloat tempv = nsgnv * (LVF(cfa[indx]) - median( Ginthv, LVFU(cfa[indx - 1]), LVFU(cfa[indx + 1]) ));
                            hcdv = vself( vmaskf_lt( temp2v, -(LVF(cfa[indx]) + Ginthv)), tempv, vintpf(hwtv, hcdv, tempv));
                            hcdv = vself( hcdmask, hcdv, hcdoldv );
                            hcdv = vself( vmaskf_gt( Ginthv, clip_ptv), tempv, hcdv);
                            STVF(hcd[indx], hcdv);

                            vfloat Gintvv = sgnv * vcdv + LVF( cfa[indx] );
                            temp2v = sgn3v * vcdv;
                            vfloat vwtv = onev + temp2v / ( epsv + Gintvv + LVF( cfa[indx]));
                            vmask vcdmask = vmaskf_gt( nsgnv * vcdv, ZEROV );
                            vfloat vcdoldv = vcdv;
                            tempv = nsgnv * (LVF(cfa[indx]) - median( Gintvv, LVF(cfa[indx - v1]), LVF(cfa[indx + v1]) ));
                            vcdv = vself( vmaskf_lt( temp2v, -(LVF(cfa[indx]) + Gintvv)), tempv, vintpf(vwtv, vcdv, tempv));
                            vcdv = vself( vcdmask, vcdv, vcdoldv );
                            vcdv = vself( vmaskf_gt( Gintvv, clip_ptv), tempv, vcdv);
                            STVF(vcd[indx], vcdv);
                            STVFU(cddiffsq[indx], SQRV(vcdv - hcdv));
                        }

                    }

#else

                    for (int rr = 4; rr < rr1 - 4; rr++) {
                        for (int cc = 4, indx = rr * ts + cc, c = fc(cfarray, rr, cc) & 1; cc < cc1 - 4; cc++, indx++) {
                            float hcdvar = 3.f * (SQR(hcd[indx - 2]) + SQR(hcd[indx]) + SQR(hcd[indx + 2])) - SQR(hcd[indx - 2] + hcd[indx] + hcd[indx + 2]);
                            float hcdaltvar = 3.f * (SQR(hcdalt[indx - 2]) + SQR(hcdalt[indx]) + SQR(hcdalt[indx + 2])) - SQR(hcdalt[indx - 2] + hcdalt[indx] + hcdalt[indx + 2]);
                            float vcdvar = 3.f * (SQR(vcd[indx - v2]) + SQR(vcd[indx]) + SQR(vcd[indx + v2])) - SQR(vcd[indx - v2] + vcd[indx] + vcd[indx + v2]);
                            float vcdaltvar = 3.f * (SQR(vcdalt[indx - v2]) + SQR(vcdalt[indx]) + SQR(vcdalt[indx + v2])) - SQR(vcdalt[indx - v2] + vcdalt[indx] + vcdalt[indx + v2]);

                            //choose the smallest variance; this yields a smoother interpolation
                            if (hcdaltvar < hcdvar) {
                                hcd[indx] = hcdalt[indx];
                            }

                            if (vcdaltvar < vcdvar) {
                                vcd[indx] = vcdalt[indx];
                            }

                            //bound the interpolation in regions of high saturation
                            //vertical and horizontal G interpolations
                            float Gintv, Ginth;

                            if (c) {//G site
                                Ginth = -hcd[indx] + cfa[indx]; //R or B
                                Gintv = -vcd[indx] + cfa[indx]; //B or R

                                if (hcd[indx] > 0) {
                                    if (3.f * hcd[indx] > (Ginth + cfa[indx])) {
                                        hcd[indx] = -median(Ginth, cfa[indx - 1], cfa[indx + 1]) + cfa[indx];
                                    } else {
                                        float hwt = 1.f - 3.f * hcd[indx] / (eps + Ginth + cfa[indx]);
                                        hcd[indx] = hwt * hcd[indx] + (1.f - hwt) * (-median(Ginth, cfa[indx - 1], cfa[indx + 1]) + cfa[indx]);
                                    }
                                }

                                if (vcd[indx] > 0) {
                                    if (3.f * vcd[indx] > (Gintv + cfa[indx])) {
                                        vcd[indx] = -median(Gintv, cfa[indx - v1], cfa[indx + v1]) + cfa[indx];
                                    } else {
                                        float vwt = 1.f - 3.f * vcd[indx] / (eps + Gintv + cfa[indx]);
                                        vcd[indx] = vwt * vcd[indx] + (1.f - vwt) * (-median(Gintv, cfa[indx - v1], cfa[indx + v1]) + cfa[indx]);
                                    }
                                }

                                if (Ginth > clip_pt) {
                                    hcd[indx] = -median(Ginth, cfa[indx - 1], cfa[indx + 1]) + cfa[indx];
                                }

                                if (Gintv > clip_pt) {
                                    vcd[indx] = -median(Gintv, cfa[indx - v1], cfa[indx + v1]) + cfa[indx];
                                }


                            } else {//R or B site

                                Ginth = hcd[indx] + cfa[indx]; //interpolated G
                                Gintv = vcd[indx] + cfa[indx];

                                if (hcd[indx] < 0) {
                                    if (3.f * hcd[indx] < -(Ginth + cfa[indx])) {
                                        hcd[indx] = median(Ginth, cfa[indx - 1], cfa[indx + 1]) - cfa[indx];
                                    } else {
                                        float hwt = 1.f + 3.f * hcd[indx] / (eps + Ginth + cfa[indx]);
                                        hcd[indx] = hwt * hcd[indx] + (1.f - hwt) * (median(Ginth, cfa[indx - 1], cfa[indx + 1]) - cfa[indx]);
                                    }
                                }

                                if (vcd[indx] < 0) {
                                    if (3.f * vcd[indx] < -(Gintv + cfa[indx])) {
                                        vcd[indx] = median(Gintv, cfa[indx - v1], cfa[indx + v1]) - cfa[indx];
                                    } else {
                                        float vwt = 1.f + 3.f * vcd[indx] / (eps + Gintv + cfa[indx]);
                                        vcd[indx] = vwt * vcd[indx] + (1.f - vwt) * (median(Gintv, cfa[indx - v1], cfa[indx + v1]) - cfa[indx]);
                                    }
                                }

                                if (Ginth > clip_pt) {
                                    hcd[indx] = median(Ginth, cfa[indx - 1], cfa[indx + 1]) - cfa[indx];
                                }

                                if (Gintv > clip_pt) {
                                    vcd[indx] = median(Gintv, cfa[indx - v1], cfa[indx + v1]) - cfa[indx];
                                }

                                cddiffsq[indx] = SQR(vcd[indx] - hcd[indx]);
                            }

                            c = !c;
                        }
                    }

#endif



#ifdef __SSE2__
                    vfloat  epssqv = F2V( epssq );

                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        for (int indx = rr * ts + 6 + (fc(cfarray, rr, 2) & 1); indx < rr * ts + cc1 - 6; indx += 8) {
                            //compute colour difference variances in cardinal directions
                            vfloat tempv = LC2VFU(vcd[indx]);
                            vfloat uavev = tempv + LC2VFU(vcd[indx - v1]) + LC2VFU(vcd[indx - v2]) + LC2VFU(vcd[indx - v3]);
                            vfloat davev = tempv + LC2VFU(vcd[indx + v1]) + LC2VFU(vcd[indx + v2]) + LC2VFU(vcd[indx + v3]);
                            vfloat Dgrbvvaruv = SQRV(tempv - uavev) + SQRV(LC2VFU(vcd[indx - v1]) - uavev) + SQRV(LC2VFU(vcd[indx - v2]) - uavev) + SQRV(LC2VFU(vcd[indx - v3]) - uavev);
                            vfloat Dgrbvvardv = SQRV(tempv - davev) + SQRV(LC2VFU(vcd[indx + v1]) - davev) + SQRV(LC2VFU(vcd[indx + v2]) - davev) + SQRV(LC2VFU(vcd[indx + v3]) - davev);

                            vfloat hwtv = vadivapb(LC2VFU(dirwts1[indx - 1]), LC2VFU(dirwts1[indx + 1]));
                            vfloat vwtv = vadivapb(LC2VFU(dirwts0[indx - v1]), LC2VFU(dirwts0[indx + v1]));

                            tempv = LC2VFU(hcd[indx]);
                            vfloat lavev = tempv + vaddc2vfu(hcd[indx - 3]) + LC2VFU(hcd[indx - 1]);
                            vfloat ravev = tempv + vaddc2vfu(hcd[indx + 1]) + LC2VFU(hcd[indx + 3]);

                            vfloat Dgrbhvarlv = SQRV(tempv - lavev) + SQRV(LC2VFU(hcd[indx - 1]) - lavev) + SQRV(LC2VFU(hcd[indx - 2]) - lavev) + SQRV(LC2VFU(hcd[indx - 3]) - lavev);
                            vfloat Dgrbhvarrv = SQRV(tempv - ravev) + SQRV(LC2VFU(hcd[indx + 1]) - ravev) + SQRV(LC2VFU(hcd[indx + 2]) - ravev) + SQRV(LC2VFU(hcd[indx + 3]) - ravev);


                            vfloat vcdvarv = epssqv + vintpf(vwtv, Dgrbvvardv, Dgrbvvaruv);
                            vfloat hcdvarv = epssqv + vintpf(hwtv, Dgrbhvarrv, Dgrbhvarlv);

                            //compute fluctuations in up/down and left/right interpolations of colours
                            Dgrbvvaruv = LC2VFU(dgintv[indx - v1]) + LC2VFU(dgintv[indx - v2]);
                            Dgrbvvardv = LC2VFU(dgintv[indx + v1]) + LC2VFU(dgintv[indx + v2]);

                            Dgrbhvarlv = vaddc2vfu(dginth[indx - 2]);
                            Dgrbhvarrv = vaddc2vfu(dginth[indx + 1]);

                            vfloat vcdvar1v = epssqv + LC2VFU(dgintv[indx]) + vintpf(vwtv, Dgrbvvardv, Dgrbvvaruv);
                            vfloat hcdvar1v = epssqv + LC2VFU(dginth[indx]) + vintpf(hwtv, Dgrbhvarrv, Dgrbhvarlv);

                            //determine adaptive weights for G interpolation
                            vfloat varwtv = hcdvarv / (vcdvarv + hcdvarv);
                            vfloat diffwtv = hcdvar1v / (vcdvar1v + hcdvar1v);

                            //if both agree on interpolation direction, choose the one with strongest directional discrimination;
                            //otherwise, choose the u/d and l/r difference fluctuation weights
                            vmask decmask = vandm( vmaskf_gt( (zd5v - varwtv) * (zd5v - diffwtv), ZEROV ), vmaskf_lt( vabsf( zd5v - diffwtv), vabsf( zd5v - varwtv) ) );
                            STVFU(hvwt[indx >> 1], vself( decmask, varwtv, diffwtv));
                        }
                    }

#else

                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        for (int cc = 6 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc; cc < cc1 - 6; cc += 2, indx += 2) {

                            //compute colour difference variances in cardinal directions

                            float uave = vcd[indx] + vcd[indx - v1] + vcd[indx - v2] + vcd[indx - v3];
                            float dave = vcd[indx] + vcd[indx + v1] + vcd[indx + v2] + vcd[indx + v3];
                            float lave = hcd[indx] + hcd[indx - 1] + hcd[indx - 2] + hcd[indx - 3];
                            float rave = hcd[indx] + hcd[indx + 1] + hcd[indx + 2] + hcd[indx + 3];

                            //colour difference (G-R or G-B) variance in up/down/left/right directions
                            float Dgrbvvaru = SQR(vcd[indx] - uave) + SQR(vcd[indx - v1] - uave) + SQR(vcd[indx - v2] - uave) + SQR(vcd[indx - v3] - uave);
                            float Dgrbvvard = SQR(vcd[indx] - dave) + SQR(vcd[indx + v1] - dave) + SQR(vcd[indx + v2] - dave) + SQR(vcd[indx + v3] - dave);
                            float Dgrbhvarl = SQR(hcd[indx] - lave) + SQR(hcd[indx - 1] - lave) + SQR(hcd[indx - 2] - lave) + SQR(hcd[indx - 3] - lave);
                            float Dgrbhvarr = SQR(hcd[indx] - rave) + SQR(hcd[indx + 1] - rave) + SQR(hcd[indx + 2] - rave) + SQR(hcd[indx + 3] - rave);

                            float hwt = dirwts1[indx - 1] / (dirwts1[indx - 1] + dirwts1[indx + 1]);
                            float vwt = dirwts0[indx - v1] / (dirwts0[indx + v1] + dirwts0[indx - v1]);

                            float vcdvar = epssq + vwt * Dgrbvvard + (1.f - vwt) * Dgrbvvaru;
                            float hcdvar = epssq + hwt * Dgrbhvarr + (1.f - hwt) * Dgrbhvarl;

                            //compute fluctuations in up/down and left/right interpolations of colours
                            Dgrbvvaru = (dgintv[indx]) + (dgintv[indx - v1]) + (dgintv[indx - v2]);
                            Dgrbvvard = (dgintv[indx]) + (dgintv[indx + v1]) + (dgintv[indx + v2]);
                            Dgrbhvarl = (dginth[indx]) + (dginth[indx - 1]) + (dginth[indx - 2]);
                            Dgrbhvarr = (dginth[indx]) + (dginth[indx + 1]) + (dginth[indx + 2]);

                            float vcdvar1 = epssq + vwt * Dgrbvvard + (1.f - vwt) * Dgrbvvaru;
                            float hcdvar1 = epssq + hwt * Dgrbhvarr + (1.f - hwt) * Dgrbhvarl;

                            //determine adaptive weights for G interpolation
                            float varwt = hcdvar / (vcdvar + hcdvar);
                            float diffwt = hcdvar1 / (vcdvar1 + hcdvar1);

                            //if both agree on interpolation direction, choose the one with strongest directional discrimination;
                            //otherwise, choose the u/d and l/r difference fluctuation weights
                            if ((0.5 - varwt) * (0.5 - diffwt) > 0 && fabsf(0.5 - diffwt) < fabsf(0.5 - varwt)) {
                                hvwt[indx >> 1] = varwt;
                            } else {
                                hvwt[indx >> 1] = diffwt;
                            }
                        }
                    }

#endif

#ifdef __SSE2__
                    vfloat gaussg0 = F2V(gaussgrad[0]);
                    vfloat gaussg1 = F2V(gaussgrad[1]);
                    vfloat gaussg2 = F2V(gaussgrad[2]);
                    vfloat gaussg3 = F2V(gaussgrad[3]);
                    vfloat gaussg4 = F2V(gaussgrad[4]);
                    vfloat gaussg5 = F2V(gaussgrad[5]);
                    vfloat gausso0 = F2V(gaussodd[0]);
                    vfloat gausso1 = F2V(gaussodd[1]);
                    vfloat gausso2 = F2V(gaussodd[2]);
                    vfloat gausso3 = F2V(gaussodd[3]);

#endif

                    // precompute nyquist
                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        int cc = 6 + (fc(cfarray, rr, 2) & 1);
                        int indx = rr * ts + cc;

#ifdef __SSE2__

                        for (; cc < cc1 - 7; cc += 8, indx += 8) {
                            vfloat valv = (gausso0 * LC2VFU(cddiffsq[indx]) +
                                           gausso1 * (LC2VFU(cddiffsq[(indx - m1)]) + LC2VFU(cddiffsq[(indx + p1)]) +
                                                      LC2VFU(cddiffsq[(indx - p1)]) + LC2VFU(cddiffsq[(indx + m1)])) +
                                           gausso2 * (LC2VFU(cddiffsq[(indx - v2)]) + LC2VFU(cddiffsq[(indx - 2)]) +
                                                      LC2VFU(cddiffsq[(indx + 2)]) + LC2VFU(cddiffsq[(indx + v2)])) +
                                           gausso3 * (LC2VFU(cddiffsq[(indx - m2)]) + LC2VFU(cddiffsq[(indx + p2)]) +
                                                      LC2VFU(cddiffsq[(indx - p2)]) + LC2VFU(cddiffsq[(indx + m2)]))) -
                                          (gaussg0 * LC2VFU(delhvsqsum[indx]) +
                                           gaussg1 * (LC2VFU(delhvsqsum[indx - v1]) + LC2VFU(delhvsqsum[indx - 1]) +
                                                      LC2VFU(delhvsqsum[indx + 1]) + LC2VFU(delhvsqsum[indx + v1])) +
                                           gaussg2 * (LC2VFU(delhvsqsum[indx - m1]) + LC2VFU(delhvsqsum[indx + p1]) +
                                                      LC2VFU(delhvsqsum[indx - p1]) + LC2VFU(delhvsqsum[indx + m1])) +
                                           gaussg3 * (LC2VFU(delhvsqsum[indx - v2]) + LC2VFU(delhvsqsum[indx - 2]) +
                                                      LC2VFU(delhvsqsum[indx + 2]) + LC2VFU(delhvsqsum[indx + v2])) +
                                           gaussg4 * (LC2VFU(delhvsqsum[indx - v2 - 1]) + LC2VFU(delhvsqsum[indx - v2 + 1]) +
                                                      LC2VFU(delhvsqsum[indx - ts - 2]) + LC2VFU(delhvsqsum[indx - ts + 2]) +
                                                      LC2VFU(delhvsqsum[indx + ts - 2]) + LC2VFU(delhvsqsum[indx + ts + 2]) +
                                                      LC2VFU(delhvsqsum[indx + v2 - 1]) + LC2VFU(delhvsqsum[indx + v2 + 1])) +
                                           gaussg5 * (LC2VFU(delhvsqsum[indx - m2]) + LC2VFU(delhvsqsum[indx + p2]) +
                                                      LC2VFU(delhvsqsum[indx - p2]) + LC2VFU(delhvsqsum[indx + m2])));
                            STVFU(nyqutest[indx >> 1], valv);

                        }

#endif

                        for (; cc < cc1 - 6; cc += 2, indx += 2) {
                            nyqutest[indx >> 1] = (gaussodd[0] * cddiffsq[indx] +
                                                   gaussodd[1] * (cddiffsq[(indx - m1)] + cddiffsq[(indx + p1)] +
                                                                  cddiffsq[(indx - p1)] + cddiffsq[(indx + m1)]) +
                                                   gaussodd[2] * (cddiffsq[(indx - v2)] + cddiffsq[(indx - 2)] +
                                                                  cddiffsq[(indx + 2)] + cddiffsq[(indx + v2)]) +
                                                   gaussodd[3] * (cddiffsq[(indx - m2)] + cddiffsq[(indx + p2)] +
                                                                  cddiffsq[(indx - p2)] + cddiffsq[(indx + m2)])) -
                                                  (gaussgrad[0] *  delhvsqsum[indx] +
                                                   gaussgrad[1] * (delhvsqsum[indx - v1] + delhvsqsum[indx + 1] +
                                                                   delhvsqsum[indx - 1] + delhvsqsum[indx + v1]) +
                                                   gaussgrad[2] * (delhvsqsum[indx - m1] + delhvsqsum[indx + p1] +
                                                                   delhvsqsum[indx - p1] + delhvsqsum[indx + m1]) +
                                                   gaussgrad[3] * (delhvsqsum[indx - v2] + delhvsqsum[indx - 2] +
                                                                   delhvsqsum[indx + 2] + delhvsqsum[indx + v2]) +
                                                   gaussgrad[4] * (delhvsqsum[indx - v2 - 1] + delhvsqsum[indx - v2 + 1] +
                                                                   delhvsqsum[indx - ts - 2] + delhvsqsum[indx - ts + 2] +
                                                                   delhvsqsum[indx + ts - 2] + delhvsqsum[indx + ts + 2] +
                                                                   delhvsqsum[indx + v2 - 1] + delhvsqsum[indx + v2 + 1]) +
                                                   gaussgrad[5] * (delhvsqsum[indx - m2] + delhvsqsum[indx + p2] +
                                                                   delhvsqsum[indx - p2] + delhvsqsum[indx + m2]));
                        }
                    }

                    // Nyquist test
                    int nystartrow = 0;
                    int nyendrow = 0;
                    int nystartcol = ts + 1;
                    int nyendcol = 0;

                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        for (int cc = 6 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc; cc < cc1 - 6; cc += 2, indx += 2) {

                            //nyquist texture test: ask if difference of vcd compared to hcd is larger or smaller than RGGB gradients
                            if(nyqutest[indx >> 1] > 0.f) {
                                nyquist[indx >> 1] = 1;    //nyquist=1 for nyquist region
                                nystartrow = nystartrow ? nystartrow : rr;
                                nyendrow = rr;
                                nystartcol = nystartcol > cc ? cc : nystartcol;
                                nyendcol = nyendcol < cc ? cc : nyendcol;
                            }
                        }
                    }


                    bool doNyquist = nystartrow != nyendrow && nystartcol != nyendcol;

                    if(doNyquist) {
                        nyendrow ++; // because of < condition
                        nyendcol ++; // because of < condition
                        nystartcol -= (nystartcol & 1);
                        nystartrow = std::max(8, nystartrow);
                        nyendrow = std::min(rr1 - 8, nyendrow);
                        nystartcol = std::max(8, nystartcol);
                        nyendcol = std::min(cc1 - 8, nyendcol);
                        memset(&nyquist2[4 * tsh], 0, sizeof(char) * (ts - 8) * tsh);

#ifdef __SSE2__
                        vint fourvb = _mm_set1_epi8(4);
                        vint onevb = _mm_set1_epi8(1);

#endif

                        for (int rr = nystartrow; rr < nyendrow; rr++) {
#ifdef __SSE2__

                            for (int indx = rr * ts; indx < rr * ts + cc1; indx += 32) {
                                vint nyquisttemp1v = _mm_adds_epi8(_mm_load_si128((vint*)&nyquist[(indx - v2) >> 1]), _mm_loadu_si128((vint*)&nyquist[(indx - m1) >> 1]));
                                vint nyquisttemp2v = _mm_adds_epi8(_mm_loadu_si128((vint*)&nyquist[(indx + p1) >> 1]), _mm_loadu_si128((vint*)&nyquist[(indx - 2) >> 1]));
                                vint nyquisttemp3v = _mm_adds_epi8(_mm_loadu_si128((vint*)&nyquist[(indx +  2) >> 1]), _mm_loadu_si128((vint*)&nyquist[(indx - p1) >> 1]));
                                vint valv = _mm_load_si128((vint*)&nyquist[indx >> 1]);
                                vint nyquisttemp4v = _mm_adds_epi8(_mm_loadu_si128((vint*)&nyquist[(indx + m1) >> 1]), _mm_load_si128((vint*)&nyquist[(indx + v2) >> 1]));
                                nyquisttemp1v = _mm_adds_epi8(nyquisttemp1v, nyquisttemp3v);
                                nyquisttemp2v = _mm_adds_epi8(nyquisttemp2v, nyquisttemp4v);
                                nyquisttemp1v = _mm_adds_epi8(nyquisttemp1v, nyquisttemp2v);
                                valv = vselc(_mm_cmpgt_epi8(nyquisttemp1v, fourvb), onevb, valv);
                                valv = vselinotzero(_mm_cmplt_epi8(nyquisttemp1v, fourvb), valv);
                                _mm_store_si128((vint*)&nyquist2[indx >> 1], valv);
                            }

#else

                            for (int indx = rr * ts + nystartcol + (fc(cfarray, rr, 2) & 1); indx < rr * ts + nyendcol; indx += 2) {
                                unsigned int nyquisttemp = (nyquist[(indx - v2) >> 1] + nyquist[(indx - m1) >> 1] + nyquist[(indx + p1) >> 1] +
                                                            nyquist[(indx - 2) >> 1] + nyquist[(indx + 2) >> 1] +
                                                            nyquist[(indx - p1) >> 1] + nyquist[(indx + m1) >> 1] + nyquist[(indx + v2) >> 1]);
                                //if most of your neighbours are named Nyquist, it's likely that you're one too, or not
                                nyquist2[indx >> 1] = nyquisttemp > 4 ? 1 : (nyquisttemp < 4 ? 0 : nyquist[indx >> 1]);
                            }

#endif
                        }

                        // end of Nyquist test

                        // in areas of Nyquist texture, do area interpolation
                        for (int rr = nystartrow; rr < nyendrow; rr++)
                            for (int indx = rr * ts + nystartcol + (fc(cfarray, rr, 2) & 1); indx < rr * ts + nyendcol; indx += 2) {

                                if (nyquist2[indx >> 1]) {
                                    // area interpolation

                                    float sumcfa = 0.f, sumh = 0.f, sumv = 0.f, sumsqh = 0.f, sumsqv = 0.f, areawt = 0.f;

                                    for (int i = -6; i < 7; i += 2) {
                                        int indx1 = indx + (i * ts) - 6;

                                        for (int j = -6; j < 7; j += 2, indx1 += 2) {
                                            if (nyquist2[indx1 >> 1]) {
                                                float cfatemp = cfa[indx1];
                                                sumcfa += cfatemp;
                                                sumh += (cfa[indx1 - 1] + cfa[indx1 + 1]);
                                                sumv += (cfa[indx1 - v1] + cfa[indx1 + v1]);
                                                sumsqh += SQR(cfatemp - cfa[indx1 - 1]) + SQR(cfatemp - cfa[indx1 + 1]);
                                                sumsqv += SQR(cfatemp - cfa[indx1 - v1]) + SQR(cfatemp - cfa[indx1 + v1]);
                                                areawt += 1;
                                            }
                                        }
                                    }

                                    //horizontal and vertical colour differences, and adaptive weight
                                    sumh = sumcfa - xdiv2f(sumh);
                                    sumv = sumcfa - xdiv2f(sumv);
                                    areawt = xdiv2f(areawt);
                                    float hcdvar = epssq + fabsf(areawt * sumsqh - sumh * sumh);
                                    float vcdvar = epssq + fabsf(areawt * sumsqv - sumv * sumv);
                                    hvwt[indx >> 1] = hcdvar / (vcdvar + hcdvar);

                                    // end of area interpolation

                                }
                            }
                    }


                    //populate G at R/B sites
                    for (int rr = 8; rr < rr1 - 8; rr++)
                        for (int indx = rr * ts + 8 + (fc(cfarray, rr, 2) & 1); indx < rr * ts + cc1 - 8; indx += 2) {

                            //first ask if one gets more directional discrimination from nearby B/R sites
                            float hvwtalt = xdivf(hvwt[(indx - m1) >> 1] + hvwt[(indx + p1) >> 1] + hvwt[(indx - p1) >> 1] + hvwt[(indx + m1) >> 1], 2);

                            hvwt[indx >> 1] = fabsf(0.5f - hvwt[indx >> 1]) < fabsf(0.5f - hvwtalt) ? hvwtalt : hvwt[indx >> 1];
                            //a better result was obtained from the neighbours

                            Dgrb[0][indx >> 1] = intp(hvwt[indx >> 1], vcd[indx], hcd[indx]); //evaluate colour differences

                            rgbgreen[indx] = cfa[indx] + Dgrb[0][indx >> 1]; //evaluate G (finally!)

                            //local curvature in G (preparation for nyquist refinement step)
                            Dgrb2[indx >> 1].h = nyquist2[indx >> 1] ? SQR(rgbgreen[indx] - xdiv2f(rgbgreen[indx - 1] + rgbgreen[indx + 1])) : 0.f;
                            Dgrb2[indx >> 1].v = nyquist2[indx >> 1] ? SQR(rgbgreen[indx] - xdiv2f(rgbgreen[indx - v1] + rgbgreen[indx + v1])) : 0.f;
                        }


                    //end of standard interpolation

                    // refine Nyquist areas using G curvatures
                    if(doNyquist) {
                        for (int rr = nystartrow; rr < nyendrow; rr++)
                            for (int indx = rr * ts + nystartcol + (fc(cfarray, rr, 2) & 1); indx < rr * ts + nyendcol; indx += 2) {

                                if (nyquist2[indx >> 1]) {
                                    //local averages (over Nyquist pixels only) of G curvature squared
                                    float gvarh = epssq + (gquinc[0] * Dgrb2[indx >> 1].h +
                                                           gquinc[1] * (Dgrb2[(indx - m1) >> 1].h + Dgrb2[(indx + p1) >> 1].h + Dgrb2[(indx - p1) >> 1].h + Dgrb2[(indx + m1) >> 1].h) +
                                                           gquinc[2] * (Dgrb2[(indx - v2) >> 1].h + Dgrb2[(indx - 2) >> 1].h + Dgrb2[(indx + 2) >> 1].h + Dgrb2[(indx + v2) >> 1].h) +
                                                           gquinc[3] * (Dgrb2[(indx - m2) >> 1].h + Dgrb2[(indx + p2) >> 1].h + Dgrb2[(indx - p2) >> 1].h + Dgrb2[(indx + m2) >> 1].h));
                                    float gvarv = epssq + (gquinc[0] * Dgrb2[indx >> 1].v +
                                                           gquinc[1] * (Dgrb2[(indx - m1) >> 1].v + Dgrb2[(indx + p1) >> 1].v + Dgrb2[(indx - p1) >> 1].v + Dgrb2[(indx + m1) >> 1].v) +
                                                           gquinc[2] * (Dgrb2[(indx - v2) >> 1].v + Dgrb2[(indx - 2) >> 1].v + Dgrb2[(indx + 2) >> 1].v + Dgrb2[(indx + v2) >> 1].v) +
                                                           gquinc[3] * (Dgrb2[(indx - m2) >> 1].v + Dgrb2[(indx + p2) >> 1].v + Dgrb2[(indx - p2) >> 1].v + Dgrb2[(indx + m2) >> 1].v));
                                    //use the results as weights for refined G interpolation
                                    Dgrb[0][indx >> 1] = (hcd[indx] * gvarv + vcd[indx] * gvarh) / (gvarv + gvarh);
                                    rgbgreen[indx] = cfa[indx] + Dgrb[0][indx >> 1];
                                }
                            }
                    }


#ifdef __SSE2__

                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        if((fc(cfarray, rr, 2) & 1) == 0) {
                            for (int cc = 6, indx = rr * ts + cc; cc < cc1 - 6; cc += 8, indx += 8) {
                                vfloat tempv = LC2VFU(cfa[indx + 1]);
                                vfloat Dgrbsq1pv = (SQRV(tempv - LC2VFU(cfa[indx + 1 - p1])) + SQRV(tempv - LC2VFU(cfa[indx + 1 + p1])));
                                STVFU(delp[indx >> 1], vabsf(LC2VFU(cfa[indx + p1]) - LC2VFU(cfa[indx - p1])));
                                STVFU(delm[indx >> 1], vabsf(LC2VFU(cfa[indx + m1]) - LC2VFU(cfa[indx - m1])));
                                vfloat Dgrbsq1mv = (SQRV(tempv - LC2VFU(cfa[indx + 1 - m1])) + SQRV(tempv - LC2VFU(cfa[indx + 1 + m1])));
                                STVFU(Dgrbsq1m[indx >> 1], Dgrbsq1mv );
                                STVFU(Dgrbsq1p[indx >> 1], Dgrbsq1pv );
                            }
                        } else {
                            for (int cc = 6, indx = rr * ts + cc; cc < cc1 - 6; cc += 8, indx += 8) {
                                vfloat tempv = LC2VFU(cfa[indx]);
                                vfloat Dgrbsq1pv = (SQRV(tempv - LC2VFU(cfa[indx - p1])) + SQRV(tempv - LC2VFU(cfa[indx + p1])));
                                STVFU(delp[indx >> 1], vabsf(LC2VFU(cfa[indx + 1 + p1]) - LC2VFU(cfa[indx + 1 - p1])));
                                STVFU(delm[indx >> 1], vabsf(LC2VFU(cfa[indx + 1 + m1]) - LC2VFU(cfa[indx + 1 - m1])));
                                vfloat Dgrbsq1mv = (SQRV(tempv - LC2VFU(cfa[indx - m1])) + SQRV(tempv - LC2VFU(cfa[indx + m1])));
                                STVFU(Dgrbsq1m[indx >> 1], Dgrbsq1mv );
                                STVFU(Dgrbsq1p[indx >> 1], Dgrbsq1pv );
                            }
                        }
                    }

#else

                    for (int rr = 6; rr < rr1 - 6; rr++) {
                        if((fc(cfarray, rr, 2) & 1) == 0) {
                            for (int cc = 6, indx = rr * ts + cc; cc < cc1 - 6; cc += 2, indx += 2) {
                                delp[indx >> 1] = fabsf(cfa[indx + p1] - cfa[indx - p1]);
                                delm[indx >> 1] = fabsf(cfa[indx + m1] - cfa[indx - m1]);
                                Dgrbsq1p[indx >> 1] = (SQR(cfa[indx + 1] - cfa[indx + 1 - p1]) + SQR(cfa[indx + 1] - cfa[indx + 1 + p1]));
                                Dgrbsq1m[indx >> 1] = (SQR(cfa[indx + 1] - cfa[indx + 1 - m1]) + SQR(cfa[indx + 1] - cfa[indx + 1 + m1]));
                            }
                        } else {
                            for (int cc = 6, indx = rr * ts + cc; cc < cc1 - 6; cc += 2, indx += 2) {
                                Dgrbsq1p[indx >> 1] = (SQR(cfa[indx] - cfa[indx - p1]) + SQR(cfa[indx] - cfa[indx + p1]));
                                Dgrbsq1m[indx >> 1] = (SQR(cfa[indx] - cfa[indx - m1]) + SQR(cfa[indx] - cfa[indx + m1]));
                                delp[indx >> 1] = fabsf(cfa[indx + 1 + p1] - cfa[indx + 1 - p1]);
                                delm[indx >> 1] = fabsf(cfa[indx + 1 + m1] - cfa[indx + 1 - m1]);
                            }
                        }
                    }

#endif

                    // diagonal interpolation correction

#ifdef __SSE2__
                    vfloat gausseven0v = F2V(gausseven[0]);
                    vfloat gausseven1v = F2V(gausseven[1]);
#endif

                    for (int rr = 8; rr < rr1 - 8; rr++) {
#ifdef __SSE2__

                        for (int indx = rr * ts + 8 + (fc(cfarray, rr, 2) & 1), indx1 = indx >> 1; indx < rr * ts + cc1 - 8; indx += 8, indx1 += 4) {

                            //diagonal colour ratios
                            vfloat cfav = LC2VFU(cfa[indx]);

                            vfloat temp1v = LC2VFU(cfa[indx + m1]);
                            vfloat temp2v = LC2VFU(cfa[indx + m2]);
                            vfloat rbsev = vmul2f(temp1v) / (epsv + cfav + temp2v );
                            rbsev = vself(vmaskf_lt(vabsf(onev - rbsev), arthreshv), cfav * rbsev, temp1v + zd5v * (cfav - temp2v));

                            temp1v = LC2VFU(cfa[indx - m1]);
                            temp2v = LC2VFU(cfa[indx - m2]);
                            vfloat rbnwv = vmul2f(temp1v) / (epsv + cfav + temp2v );
                            rbnwv = vself(vmaskf_lt(vabsf(onev - rbnwv), arthreshv), cfav * rbnwv, temp1v + zd5v * (cfav - temp2v));

                            temp1v = epsv + LVFU(delm[indx1]);
                            vfloat wtsev = temp1v + LVFU(delm[(indx + m1) >> 1]) + LVFU(delm[(indx + m2) >> 1]); //same as for wtu,wtd,wtl,wtr
                            vfloat wtnwv = temp1v + LVFU(delm[(indx - m1) >> 1]) + LVFU(delm[(indx - m2) >> 1]);

                            vfloat rbmv = (wtsev * rbnwv + wtnwv * rbsev) / (wtsev + wtnwv);

                            temp1v = median(rbmv , LC2VFU(cfa[indx - m1]), LC2VFU(cfa[indx + m1]));
                            vfloat wtv = vmul2f(cfav - rbmv) / (epsv + rbmv + cfav);
                            temp2v = vintpf(wtv, rbmv, temp1v);

                            temp2v = vself(vmaskf_lt(rbmv + rbmv, cfav), temp1v, temp2v);
                            temp2v = vself(vmaskf_lt(rbmv, cfav), temp2v, rbmv);
                            STVFU(rbm[indx1], vself(vmaskf_gt(temp2v, clip_ptv), median(temp2v , LC2VFU(cfa[indx - m1]), LC2VFU(cfa[indx + m1])), temp2v ));


                            temp1v = LC2VFU(cfa[indx + p1]);
                            temp2v = LC2VFU(cfa[indx + p2]);
                            vfloat rbnev = vmul2f(temp1v) / (epsv + cfav + temp2v );
                            rbnev = vself(vmaskf_lt(vabsf(onev - rbnev), arthreshv), cfav * rbnev, temp1v + zd5v * (cfav - temp2v));

                            temp1v = LC2VFU(cfa[indx - p1]);
                            temp2v = LC2VFU(cfa[indx - p2]);
                            vfloat rbswv = vmul2f(temp1v) / (epsv + cfav + temp2v );
                            rbswv = vself(vmaskf_lt(vabsf(onev - rbswv), arthreshv), cfav * rbswv, temp1v + zd5v * (cfav - temp2v));

                            temp1v = epsv + LVFU(delp[indx1]);
                            vfloat wtnev = temp1v + LVFU(delp[(indx + p1) >> 1]) + LVFU(delp[(indx + p2) >> 1]);
                            vfloat wtswv = temp1v + LVFU(delp[(indx - p1) >> 1]) + LVFU(delp[(indx - p2) >> 1]);

                            vfloat rbpv = (wtnev * rbswv + wtswv * rbnev) / (wtnev + wtswv);

                            temp1v = median(rbpv , LC2VFU(cfa[indx - p1]), LC2VFU(cfa[indx + p1]));
                            wtv = vmul2f(cfav - rbpv) / (epsv + rbpv + cfav);
                            temp2v = vintpf(wtv, rbpv, temp1v);

                            temp2v = vself(vmaskf_lt(rbpv + rbpv, cfav), temp1v, temp2v);
                            temp2v = vself(vmaskf_lt(rbpv, cfav), temp2v, rbpv);
                            STVFU(rbp[indx1], vself(vmaskf_gt(temp2v, clip_ptv), median(temp2v , LC2VFU(cfa[indx - p1]), LC2VFU(cfa[indx + p1])), temp2v ));

                            vfloat rbvarmv = epssqv + (gausseven0v * (LVFU(Dgrbsq1m[(indx - v1) >> 1]) + LVFU(Dgrbsq1m[(indx - 1) >> 1]) + LVFU(Dgrbsq1m[(indx + 1) >> 1]) + LVFU(Dgrbsq1m[(indx + v1) >> 1])) +
                                                       gausseven1v * (LVFU(Dgrbsq1m[(indx - v2 - 1) >> 1]) + LVFU(Dgrbsq1m[(indx - v2 + 1) >> 1]) + LVFU(Dgrbsq1m[(indx - 2 - v1) >> 1]) + LVFU(Dgrbsq1m[(indx + 2 - v1) >> 1]) +
                                                               LVFU(Dgrbsq1m[(indx - 2 + v1) >> 1]) + LVFU(Dgrbsq1m[(indx + 2 + v1) >> 1]) + LVFU(Dgrbsq1m[(indx + v2 - 1) >> 1]) + LVFU(Dgrbsq1m[(indx + v2 + 1) >> 1])));
                            STVFU(pmwt[indx1] , rbvarmv / ((epssqv + (gausseven0v * (LVFU(Dgrbsq1p[(indx - v1) >> 1]) + LVFU(Dgrbsq1p[(indx - 1) >> 1]) + LVFU(Dgrbsq1p[(indx + 1) >> 1]) + LVFU(Dgrbsq1p[(indx + v1) >> 1])) +
                                                            gausseven1v * (LVFU(Dgrbsq1p[(indx - v2 - 1) >> 1]) + LVFU(Dgrbsq1p[(indx - v2 + 1) >> 1]) + LVFU(Dgrbsq1p[(indx - 2 - v1) >> 1]) + LVFU(Dgrbsq1p[(indx + 2 - v1) >> 1]) +
                                                                    LVFU(Dgrbsq1p[(indx - 2 + v1) >> 1]) + LVFU(Dgrbsq1p[(indx + 2 + v1) >> 1]) + LVFU(Dgrbsq1p[(indx + v2 - 1) >> 1]) + LVFU(Dgrbsq1p[(indx + v2 + 1) >> 1])))) + rbvarmv));

                        }

#else

                        for (int cc = 8 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc, indx1 = indx >> 1; cc < cc1 - 8; cc += 2, indx += 2, indx1++) {

                            //diagonal colour ratios
                            float crse = xmul2f(cfa[indx + m1]) / (eps + cfa[indx] + (cfa[indx + m2]));
                            float crnw = xmul2f(cfa[indx - m1]) / (eps + cfa[indx] + (cfa[indx - m2]));
                            float crne = xmul2f(cfa[indx + p1]) / (eps + cfa[indx] + (cfa[indx + p2]));
                            float crsw = xmul2f(cfa[indx - p1]) / (eps + cfa[indx] + (cfa[indx - p2]));
                            //colour differences in diagonal directions
                            float rbse, rbnw, rbne, rbsw;

                            //assign B/R at R/B sites
                            if (fabsf(1.f - crse) < arthresh) {
                                rbse = cfa[indx] * crse;    //use this if more precise diag interp is necessary
                            } else {
                                rbse = (cfa[indx + m1]) + xdiv2f(cfa[indx] - cfa[indx + m2]);
                            }

                            if (fabsf(1.f - crnw) < arthresh) {
                                rbnw = cfa[indx] * crnw;
                            } else {
                                rbnw = (cfa[indx - m1]) + xdiv2f(cfa[indx] - cfa[indx - m2]);
                            }

                            if (fabsf(1.f - crne) < arthresh) {
                                rbne = cfa[indx] * crne;
                            } else {
                                rbne = (cfa[indx + p1]) + xdiv2f(cfa[indx] - cfa[indx + p2]);
                            }

                            if (fabsf(1.f - crsw) < arthresh) {
                                rbsw = cfa[indx] * crsw;
                            } else {
                                rbsw = (cfa[indx - p1]) + xdiv2f(cfa[indx] - cfa[indx - p2]);
                            }

                            float wtse = eps + delm[indx1] + delm[(indx + m1) >> 1] + delm[(indx + m2) >> 1]; //same as for wtu,wtd,wtl,wtr
                            float wtnw = eps + delm[indx1] + delm[(indx - m1) >> 1] + delm[(indx - m2) >> 1];
                            float wtne = eps + delp[indx1] + delp[(indx + p1) >> 1] + delp[(indx + p2) >> 1];
                            float wtsw = eps + delp[indx1] + delp[(indx - p1) >> 1] + delp[(indx - p2) >> 1];


                            rbm[indx1] = (wtse * rbnw + wtnw * rbse) / (wtse + wtnw);
                            rbp[indx1] = (wtne * rbsw + wtsw * rbne) / (wtne + wtsw);

                            //variance of R-B in plus/minus directions
                            float rbvarm = epssq + (gausseven[0] * (Dgrbsq1m[(indx - v1) >> 1] + Dgrbsq1m[(indx - 1) >> 1] + Dgrbsq1m[(indx + 1) >> 1] + Dgrbsq1m[(indx + v1) >> 1]) +
                                                    gausseven[1] * (Dgrbsq1m[(indx - v2 - 1) >> 1] + Dgrbsq1m[(indx - v2 + 1) >> 1] + Dgrbsq1m[(indx - 2 - v1) >> 1] + Dgrbsq1m[(indx + 2 - v1) >> 1] +
                                                                    Dgrbsq1m[(indx - 2 + v1) >> 1] + Dgrbsq1m[(indx + 2 + v1) >> 1] + Dgrbsq1m[(indx + v2 - 1) >> 1] + Dgrbsq1m[(indx + v2 + 1) >> 1]));
                            pmwt[indx1] = rbvarm / ((epssq + (gausseven[0] * (Dgrbsq1p[(indx - v1) >> 1] + Dgrbsq1p[(indx - 1) >> 1] + Dgrbsq1p[(indx + 1) >> 1] + Dgrbsq1p[(indx + v1) >> 1]) +
                                                              gausseven[1] * (Dgrbsq1p[(indx - v2 - 1) >> 1] + Dgrbsq1p[(indx - v2 + 1) >> 1] + Dgrbsq1p[(indx - 2 - v1) >> 1] + Dgrbsq1p[(indx + 2 - v1) >> 1] +
                                                                      Dgrbsq1p[(indx - 2 + v1) >> 1] + Dgrbsq1p[(indx + 2 + v1) >> 1] + Dgrbsq1p[(indx + v2 - 1) >> 1] + Dgrbsq1p[(indx + v2 + 1) >> 1]))) + rbvarm);

                            //bound the interpolation in regions of high saturation

                            if (rbp[indx1] < cfa[indx]) {
                                if (xmul2f(rbp[indx1]) < cfa[indx]) {
                                    rbp[indx1] = median(rbp[indx1] , cfa[indx - p1], cfa[indx + p1]);
                                } else {
                                    float pwt = xmul2f(cfa[indx] - rbp[indx1]) / (eps + rbp[indx1] + cfa[indx]);
                                    rbp[indx1] = pwt * rbp[indx1] + (1.f - pwt) * median(rbp[indx1], cfa[indx - p1], cfa[indx + p1]);
                                }
                            }

                            if (rbm[indx1] < cfa[indx]) {
                                if (xmul2f(rbm[indx1]) < cfa[indx]) {
                                    rbm[indx1] = median(rbm[indx1] , cfa[indx - m1], cfa[indx + m1]);
                                } else {
                                    float mwt = xmul2f(cfa[indx] - rbm[indx1]) / (eps + rbm[indx1] + cfa[indx]);
                                    rbm[indx1] = mwt * rbm[indx1] + (1.f - mwt) * median(rbm[indx1], cfa[indx - m1], cfa[indx + m1]);
                                }
                            }

                            if (rbp[indx1] > clip_pt) {
                                rbp[indx1] = median(rbp[indx1], cfa[indx - p1], cfa[indx + p1]);
                            }

                            if (rbm[indx1] > clip_pt) {
                                rbm[indx1] = median(rbm[indx1], cfa[indx - m1], cfa[indx + m1]);
                            }
                        }

#endif
                    }

#ifdef __SSE2__
                    vfloat zd25v = F2V(0.25f);
#endif

                    for (int rr = 10; rr < rr1 - 10; rr++)
#ifdef __SSE2__
                        for (int indx = rr * ts + 10 + (fc(cfarray, rr, 2) & 1), indx1 = indx >> 1; indx < rr * ts + cc1 - 10; indx += 8, indx1 += 4) {

                            //first ask if one gets more directional discrimination from nearby B/R sites
                            vfloat pmwtaltv = zd25v * (LVFU(pmwt[(indx - m1) >> 1]) + LVFU(pmwt[(indx + p1) >> 1]) + LVFU(pmwt[(indx - p1) >> 1]) + LVFU(pmwt[(indx + m1) >> 1]));
                            vfloat tempv = LVFU(pmwt[indx1]);
                            tempv = vself(vmaskf_lt(vabsf(zd5v - tempv), vabsf(zd5v - pmwtaltv)), pmwtaltv, tempv);
                            STVFU(pmwt[indx1], tempv);
                            STVFU(rbint[indx1], zd5v * (LC2VFU(cfa[indx]) + vintpf(tempv, LVFU(rbp[indx1]), LVFU(rbm[indx1]))));
                        }

#else

                        for (int cc = 10 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc, indx1 = indx >> 1; cc < cc1 - 10; cc += 2, indx += 2, indx1++) {

                            //first ask if one gets more directional discrimination from nearby B/R sites
                            float pmwtalt = xdivf(pmwt[(indx - m1) >> 1] + pmwt[(indx + p1) >> 1] + pmwt[(indx - p1) >> 1] + pmwt[(indx + m1) >> 1], 2);

                            if (fabsf(0.5 - pmwt[indx1]) < fabsf(0.5 - pmwtalt)) {
                                pmwt[indx1] = pmwtalt;   //a better result was obtained from the neighbours
                            }

                            rbint[indx1] = xdiv2f(cfa[indx] + rbm[indx1] * (1.f - pmwt[indx1]) + rbp[indx1] * pmwt[indx1]); //this is R+B, interpolated
                        }

#endif

                    for (int rr = 12; rr < rr1 - 12; rr++)
#ifdef __SSE2__
                        for (int indx = rr * ts + 12 + (fc(cfarray, rr, 2) & 1), indx1 = indx >> 1; indx < rr * ts + cc1 - 12; indx += 8, indx1 += 4) {
                            vmask copymask = vmaskf_ge(vabsf(zd5v - LVFU(pmwt[indx1])), vabsf(zd5v - LVFU(hvwt[indx1])));

                            if(_mm_movemask_ps((vfloat)copymask)) { // if for any of the 4 pixels the condition is true, do the maths for all 4 pixels and mask the unused out at the end
                                //now interpolate G vertically/horizontally using R+B values
                                //unfortunately, since G interpolation cannot be done diagonally this may lead to colour shifts
                                //colour ratios for G interpolation
                                vfloat rbintv = LVFU(rbint[indx1]);

                                //interpolated G via adaptive ratios or Hamilton-Adams in each cardinal direction
                                vfloat cruv = vmul2f(LC2VFU(cfa[indx - v1])) / (epsv + rbintv + LVFU(rbint[(indx1 - v1)]));
                                vfloat guv = rbintv * cruv;
                                vfloat gu2v = LC2VFU(cfa[indx - v1]) + zd5v * (rbintv - LVFU(rbint[(indx1 - v1)]));
                                guv = vself(vmaskf_lt(vabsf(onev - cruv), arthreshv), guv, gu2v);

                                vfloat crdv = vmul2f(LC2VFU(cfa[indx + v1])) / (epsv + rbintv + LVFU(rbint[(indx1 + v1)]));
                                vfloat gdv = rbintv * crdv;
                                vfloat gd2v = LC2VFU(cfa[indx + v1]) + zd5v * (rbintv - LVFU(rbint[(indx1 + v1)]));
                                gdv = vself(vmaskf_lt(vabsf(onev - crdv), arthreshv), gdv, gd2v);

                                vfloat Gintvv = (LC2VFU(dirwts0[indx - v1]) * gdv + LC2VFU(dirwts0[indx + v1]) * guv) / (LC2VFU(dirwts0[indx + v1]) + LC2VFU(dirwts0[indx - v1]));
                                vfloat Gint1v = median(Gintvv , LC2VFU(cfa[indx - v1]), LC2VFU(cfa[indx + v1]));
                                vfloat vwtv = vmul2f(rbintv - Gintvv) / (epsv + Gintvv + rbintv);
                                vfloat Gint2v = vintpf(vwtv, Gintvv, Gint1v);
                                Gint1v = vself(vmaskf_lt(vmul2f(Gintvv), rbintv), Gint1v, Gint2v);
                                Gintvv = vself(vmaskf_lt(Gintvv, rbintv), Gint1v, Gintvv);
                                Gintvv = vself(vmaskf_gt(Gintvv, clip_ptv), median(Gintvv, LC2VFU(cfa[indx - v1]), LC2VFU(cfa[indx + v1])), Gintvv);

                                vfloat crlv = vmul2f(LC2VFU(cfa[indx - 1])) / (epsv + rbintv + LVFU(rbint[(indx1 - 1)]));
                                vfloat glv = rbintv * crlv;
                                vfloat gl2v = LC2VFU(cfa[indx - 1]) + zd5v * (rbintv - LVFU(rbint[(indx1 - 1)]));
                                glv = vself(vmaskf_lt(vabsf(onev - crlv), arthreshv), glv, gl2v);

                                vfloat crrv = vmul2f(LC2VFU(cfa[indx + 1])) / (epsv + rbintv + LVFU(rbint[(indx1 + 1)]));
                                vfloat grv = rbintv * crrv;
                                vfloat gr2v = LC2VFU(cfa[indx + 1]) + zd5v * (rbintv - LVFU(rbint[(indx1 + 1)]));
                                grv = vself(vmaskf_lt(vabsf(onev - crrv), arthreshv), grv, gr2v);

                                vfloat Ginthv = (LC2VFU(dirwts1[indx - 1]) * grv + LC2VFU(dirwts1[indx + 1]) * glv) / (LC2VFU(dirwts1[indx - 1]) + LC2VFU(dirwts1[indx + 1]));
                                vfloat Gint1h = median(Ginthv , LC2VFU(cfa[indx - 1]), LC2VFU(cfa[indx + 1]));
                                vfloat hwtv = vmul2f(rbintv - Ginthv) / (epsv + Ginthv + rbintv);
                                vfloat Gint2h = vintpf(hwtv, Ginthv, Gint1h);
                                Gint1h = vself(vmaskf_lt(vmul2f(Ginthv), rbintv), Gint1h, Gint2h);
                                Ginthv = vself(vmaskf_lt(Ginthv, rbintv), Gint1h, Ginthv);
                                Ginthv = vself(vmaskf_gt(Ginthv, clip_ptv), median(Ginthv, LC2VFU(cfa[indx - 1]), LC2VFU(cfa[indx + 1])), Ginthv);

                                vfloat greenv = vself(copymask, vintpf(LVFU(hvwt[indx1]), Gintvv, Ginthv), LC2VFU(rgbgreen[indx]));
                                STC2VFU(rgbgreen[indx], greenv);

                                STVFU(Dgrb[0][indx1], vself(copymask, greenv - LC2VFU(cfa[indx]), LVFU(Dgrb[0][indx1])));
                            }
                        }

#else

                        for (int cc = 12 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc, indx1 = indx >> 1; cc < cc1 - 12; cc += 2, indx += 2, indx1++) {

                            if (fabsf(0.5 - pmwt[indx >> 1]) < fabsf(0.5 - hvwt[indx >> 1]) ) {
                                continue;
                            }

                            //now interpolate G vertically/horizontally using R+B values
                            //unfortunately, since G interpolation cannot be done diagonally this may lead to colour shifts

                            //colour ratios for G interpolation
                            float cru = cfa[indx - v1] * 2.0 / (eps + rbint[indx1] + rbint[(indx1 - v1)]);
                            float crd = cfa[indx + v1] * 2.0 / (eps + rbint[indx1] + rbint[(indx1 + v1)]);
                            float crl = cfa[indx - 1] * 2.0 / (eps + rbint[indx1] + rbint[(indx1 - 1)]);
                            float crr = cfa[indx + 1] * 2.0 / (eps + rbint[indx1] + rbint[(indx1 + 1)]);

                            //interpolation of G in four directions
                            float gu, gd, gl, gr;

                            //interpolated G via adaptive ratios or Hamilton-Adams in each cardinal direction
                            if (fabsf(1.f - cru) < arthresh) {
                                gu = rbint[indx1] * cru;
                            } else {
                                gu = cfa[indx - v1] + xdiv2f(rbint[indx1] - rbint[(indx1 - v1)]);
                            }

                            if (fabsf(1.f - crd) < arthresh) {
                                gd = rbint[indx1] * crd;
                            } else {
                                gd = cfa[indx + v1] + xdiv2f(rbint[indx1] - rbint[(indx1 + v1)]);
                            }

                            if (fabsf(1.f - crl) < arthresh) {
                                gl = rbint[indx1] * crl;
                            } else {
                                gl = cfa[indx - 1] + xdiv2f(rbint[indx1] - rbint[(indx1 - 1)]);
                            }

                            if (fabsf(1.f - crr) < arthresh) {
                                gr = rbint[indx1] * crr;
                            } else {
                                gr = cfa[indx + 1] + xdiv2f(rbint[indx1] - rbint[(indx1 + 1)]);
                            }

                            //interpolated G via adaptive weights of cardinal evaluations
                            float Gintv = (dirwts0[indx - v1] * gd + dirwts0[indx + v1] * gu) / (dirwts0[indx + v1] + dirwts0[indx - v1]);
                            float Ginth = (dirwts1[indx - 1] * gr + dirwts1[indx + 1] * gl) / (dirwts1[indx - 1] + dirwts1[indx + 1]);

                            //bound the interpolation in regions of high saturation
                            if (Gintv < rbint[indx1]) {
                                if (2 * Gintv < rbint[indx1]) {
                                    Gintv = median(Gintv , cfa[indx - v1], cfa[indx + v1]);
                                } else {
                                    float vwt = 2.0 * (rbint[indx1] - Gintv) / (eps + Gintv + rbint[indx1]);
                                    Gintv = vwt * Gintv + (1.f - vwt) * median(Gintv, cfa[indx - v1], cfa[indx + v1]);
                                }
                            }

                            if (Ginth < rbint[indx1]) {
                                if (2 * Ginth < rbint[indx1]) {
                                    Ginth = median(Ginth , cfa[indx - 1], cfa[indx + 1]);
                                } else {
                                    float hwt = 2.0 * (rbint[indx1] - Ginth) / (eps + Ginth + rbint[indx1]);
                                    Ginth = hwt * Ginth + (1.f - hwt) * median(Ginth, cfa[indx - 1], cfa[indx + 1]);
                                }
                            }

                            if (Ginth > clip_pt) {
                                Ginth = median(Ginth, cfa[indx - 1], cfa[indx + 1]);
                            }

                            if (Gintv > clip_pt) {
                                Gintv = median(Gintv, cfa[indx - v1], cfa[indx + v1]);
                            }

                            rgbgreen[indx] = Ginth * (1.f - hvwt[indx1]) + Gintv * hvwt[indx1];
                            Dgrb[0][indx >> 1] = rgbgreen[indx] - cfa[indx];
                        }

#endif

                    //end of diagonal interpolation correction

                    //fancy chrominance interpolation
                    //(ey,ex) is location of R site
                    for (int rr = 13 - ey; rr < rr1 - 12; rr += 2)
                        for (int indx1 = (rr * ts + 13 - ex) >> 1; indx1 < (rr * ts + cc1 - 12) >> 1; indx1++) { //B coset
                            Dgrb[1][indx1] = Dgrb[0][indx1]; //split out G-B from G-R
                            Dgrb[0][indx1] = 0;
                        }

#ifdef __SSE2__
                    vfloat oned325v = F2V( 1.325f );
                    vfloat zd175v = F2V( 0.175f );
                    vfloat zd075v = F2V( 0.075f );
#endif

                    for (int rr = 14; rr < rr1 - 14; rr++)
#ifdef __SSE2__
                        for (int cc = 14 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc, c = 1 - fc(cfarray, rr, cc) / 2; cc < cc1 - 14; cc += 8, indx += 8) {
                            vfloat tempv = epsv + vabsf(LVFU(Dgrb[c][(indx - m1) >> 1]) - LVFU(Dgrb[c][(indx + m1) >> 1]));
                            vfloat temp2v = epsv + vabsf(LVFU(Dgrb[c][(indx + p1) >> 1]) - LVFU(Dgrb[c][(indx - p1) >> 1]));
                            vfloat wtnwv = onev / (tempv + vabsf(LVFU(Dgrb[c][(indx - m1) >> 1]) - LVFU(Dgrb[c][(indx - m3) >> 1])) + vabsf(LVFU(Dgrb[c][(indx + m1) >> 1]) - LVFU(Dgrb[c][(indx - m3) >> 1])));
                            vfloat wtnev = onev / (temp2v + vabsf(LVFU(Dgrb[c][(indx + p1) >> 1]) - LVFU(Dgrb[c][(indx + p3) >> 1])) + vabsf(LVFU(Dgrb[c][(indx - p1) >> 1]) - LVFU(Dgrb[c][(indx + p3) >> 1])));
                            vfloat wtswv = onev / (temp2v + vabsf(LVFU(Dgrb[c][(indx - p1) >> 1]) - LVFU(Dgrb[c][(indx + m3) >> 1])) + vabsf(LVFU(Dgrb[c][(indx + p1) >> 1]) - LVFU(Dgrb[c][(indx - p3) >> 1])));
                            vfloat wtsev = onev / (tempv + vabsf(LVFU(Dgrb[c][(indx + m1) >> 1]) - LVFU(Dgrb[c][(indx - p3) >> 1])) + vabsf(LVFU(Dgrb[c][(indx - m1) >> 1]) - LVFU(Dgrb[c][(indx + m3) >> 1])));

                            STVFU(Dgrb[c][indx >> 1], (wtnwv * (oned325v * LVFU(Dgrb[c][(indx - m1) >> 1]) - zd175v * LVFU(Dgrb[c][(indx - m3) >> 1]) - zd075v * (LVFU(Dgrb[c][(indx - m1 - 2) >> 1]) + LVFU(Dgrb[c][(indx - m1 - v2) >> 1])) ) +
                                                       wtnev * (oned325v * LVFU(Dgrb[c][(indx + p1) >> 1]) - zd175v * LVFU(Dgrb[c][(indx + p3) >> 1]) - zd075v * (LVFU(Dgrb[c][(indx + p1 + 2) >> 1]) + LVFU(Dgrb[c][(indx + p1 + v2) >> 1])) ) +
                                                       wtswv * (oned325v * LVFU(Dgrb[c][(indx - p1) >> 1]) - zd175v * LVFU(Dgrb[c][(indx - p3) >> 1]) - zd075v * (LVFU(Dgrb[c][(indx - p1 - 2) >> 1]) + LVFU(Dgrb[c][(indx - p1 - v2) >> 1])) ) +
                                                       wtsev * (oned325v * LVFU(Dgrb[c][(indx + m1) >> 1]) - zd175v * LVFU(Dgrb[c][(indx + m3) >> 1]) - zd075v * (LVFU(Dgrb[c][(indx + m1 + 2) >> 1]) + LVFU(Dgrb[c][(indx + m1 + v2) >> 1])) )) / (wtnwv + wtnev + wtswv + wtsev));
                        }

#else

                        for (int cc = 14 + (fc(cfarray, rr, 2) & 1), indx = rr * ts + cc, c = 1 - fc(cfarray, rr, cc) / 2; cc < cc1 - 14; cc += 2, indx += 2) {
                            float wtnw = 1.f / (eps + fabsf(Dgrb[c][(indx - m1) >> 1] - Dgrb[c][(indx + m1) >> 1]) + fabsf(Dgrb[c][(indx - m1) >> 1] - Dgrb[c][(indx - m3) >> 1]) + fabsf(Dgrb[c][(indx + m1) >> 1] - Dgrb[c][(indx - m3) >> 1]));
                            float wtne = 1.f / (eps + fabsf(Dgrb[c][(indx + p1) >> 1] - Dgrb[c][(indx - p1) >> 1]) + fabsf(Dgrb[c][(indx + p1) >> 1] - Dgrb[c][(indx + p3) >> 1]) + fabsf(Dgrb[c][(indx - p1) >> 1] - Dgrb[c][(indx + p3) >> 1]));
                            float wtsw = 1.f / (eps + fabsf(Dgrb[c][(indx - p1) >> 1] - Dgrb[c][(indx + p1) >> 1]) + fabsf(Dgrb[c][(indx - p1) >> 1] - Dgrb[c][(indx + m3) >> 1]) + fabsf(Dgrb[c][(indx + p1) >> 1] - Dgrb[c][(indx - p3) >> 1]));
                            float wtse = 1.f / (eps + fabsf(Dgrb[c][(indx + m1) >> 1] - Dgrb[c][(indx - m1) >> 1]) + fabsf(Dgrb[c][(indx + m1) >> 1] - Dgrb[c][(indx - p3) >> 1]) + fabsf(Dgrb[c][(indx - m1) >> 1] - Dgrb[c][(indx + m3) >> 1]));

                            Dgrb[c][indx >> 1] = (wtnw * (1.325f * Dgrb[c][(indx - m1) >> 1] - 0.175f * Dgrb[c][(indx - m3) >> 1] - 0.075f * Dgrb[c][(indx - m1 - 2) >> 1] - 0.075f * Dgrb[c][(indx - m1 - v2) >> 1] ) +
                                                  wtne * (1.325f * Dgrb[c][(indx + p1) >> 1] - 0.175f * Dgrb[c][(indx + p3) >> 1] - 0.075f * Dgrb[c][(indx + p1 + 2) >> 1] - 0.075f * Dgrb[c][(indx + p1 + v2) >> 1] ) +
                                                  wtsw * (1.325f * Dgrb[c][(indx - p1) >> 1] - 0.175f * Dgrb[c][(indx - p3) >> 1] - 0.075f * Dgrb[c][(indx - p1 - 2) >> 1] - 0.075f * Dgrb[c][(indx - p1 - v2) >> 1] ) +
                                                  wtse * (1.325f * Dgrb[c][(indx + m1) >> 1] - 0.175f * Dgrb[c][(indx + m3) >> 1] - 0.075f * Dgrb[c][(indx + m1 + 2) >> 1] - 0.075f * Dgrb[c][(indx + m1 + v2) >> 1] )) / (wtnw + wtne + wtsw + wtse);
                        }

#endif

#ifdef __SSE2__
                    int offset;
                    vfloat twov = F2V(2.f);
                    vfloat coutscalev = F2V(outputScale);
                    vmask selmask;

                    if((fc(cfarray, 16, 2) & 1) == 1) {
                        selmask = _mm_set_epi32(0xffffffff, 0, 0xffffffff, 0);
                        offset = 1;
                    } else {
                        selmask = _mm_set_epi32(0, 0xffffffff, 0, 0xffffffff);
                        offset = 0;
                    }

#endif

                    for (int rr = 16; rr < rr1 - 16; rr++) {
                        int row = rr + top;
                        int col = left + 16;
                        int indx = rr * ts + 16;
#ifdef __SSE2__
                        offset = 1 - offset;
                        selmask = vnotm(selmask);

                        for (; indx < rr * ts + cc1 - 18 - (cc1 & 1); indx += 4, col += 4) {
                            vfloat greenv = LVF(rgbgreen[indx]);
                            vfloat temp00v = vdup(LVFU(hvwt[(indx - v1) >> 1]));
                            vfloat temp01v = vdup(LVFU(hvwt[(indx + v1) >> 1]));
                            vfloat tempv =  onev / (temp00v + twov - vdup(LVFU(hvwt[(indx + 1 + offset) >> 1])) - vdup(LVFU(hvwt[(indx - 1 + offset) >> 1])) + temp01v);

                            vfloat redv1  = greenv - (temp00v * vdup(LVFU(Dgrb[0][(indx - v1) >> 1])) + (onev - vdup(LVFU(hvwt[(indx + 1 + offset) >> 1]))) * vdup(LVFU(Dgrb[0][(indx + 1 + offset) >> 1])) + (onev - vdup(LVFU(hvwt[(indx - 1 + offset) >> 1]))) * vdup(LVFU(Dgrb[0][(indx - 1 + offset) >> 1])) + temp01v * vdup(LVFU(Dgrb[0][(indx + v1) >> 1]))) * tempv;
                            vfloat bluev1 = greenv - (temp00v * vdup(LVFU(Dgrb[1][(indx - v1) >> 1])) + (onev - vdup(LVFU(hvwt[(indx + 1 + offset) >> 1]))) * vdup(LVFU(Dgrb[1][(indx + 1 + offset) >> 1])) + (onev - vdup(LVFU(hvwt[(indx - 1 + offset) >> 1]))) * vdup(LVFU(Dgrb[1][(indx - 1 + offset) >> 1])) + temp01v * vdup(LVFU(Dgrb[1][(indx + v1) >> 1]))) * tempv;
                            vfloat redv2  = greenv - vdup(LVFU(Dgrb[0][indx >> 1]));
                            vfloat bluev2 = greenv - vdup(LVFU(Dgrb[1][indx >> 1]));
                            STVFU(red[row][col], coutscalev * vself(selmask, redv1, redv2));
                            STVFU(blue[row][col], coutscalev * vself(selmask, bluev1, bluev2));
                        }

                        if(offset == 0) {
                            for (; indx < rr * ts + cc1 - 16 - (cc1 & 1); indx++, col++) {
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);

                                indx++;
                                col++;
                                red[row][col] = outputScale * (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);
                            }

                            if(cc1 & 1) { // width of tile is odd
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);
                            }
                        } else {
                            for (; indx < rr * ts + cc1 - 16 - (cc1 & 1); indx++, col++) {
                                red[row][col] = outputScale * (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);

                                indx++;
                                col++;
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);
                            }

                            if(cc1 & 1) { // width of tile is odd
                                red[row][col] = outputScale * (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);
                            }
                        }

#else

                        if((fc(cfarray, rr, 2) & 1) == 1) {
                            for (; indx < rr * ts + cc1 - 16 - (cc1 & 1); indx++, col++) {
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);

                                indx++;
                                col++;
                                red[row][col] = outputScale* (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);
                            }

                            if(cc1 & 1) { // width of tile is odd
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);
                            }
                        } else {
                            for (; indx < rr * ts + cc1 - 16 - (cc1 & 1); indx++, col++) {
                                red[row][col] = outputScale * (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);

                                indx++;
                                col++;
                                float temp =  1.f / (hvwt[(indx - v1) >> 1] + 2.f - hvwt[(indx + 1) >> 1] - hvwt[(indx - 1) >> 1] + hvwt[(indx + v1) >> 1]);
                                red[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[0][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[0][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[0][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[0][(indx + v1) >> 1]) *
                                                            temp);
                                blue[row][col] = outputScale * (rgbgreen[indx] - ((hvwt[(indx - v1) >> 1]) * Dgrb[1][(indx - v1) >> 1] + (1.f - hvwt[(indx + 1) >> 1]) * Dgrb[1][(indx + 1) >> 1] + (1.f - hvwt[(indx - 1) >> 1]) * Dgrb[1][(indx - 1) >> 1] + (hvwt[(indx + v1) >> 1]) * Dgrb[1][(indx + v1) >> 1]) *
                                                             temp);
                            }

                            if(cc1 & 1) { // width of tile is odd
                                red[row][col] = outputScale * (rgbgreen[indx] - Dgrb[0][indx >> 1]);
                                blue[row][col] = outputScale * (rgbgreen[indx] - Dgrb[1][indx >> 1]);
                            }
                        }

#endif
                    }

                    // copy smoothed results back to image matrix
                    for (int rr = 16; rr < rr1 - 16; rr++) {
                        int row = rr + top;
                        int cc = 16;
#ifdef __SSE2__

                        for (; cc < cc1 - 19; cc += 4) {
                            STVFU(green[row][cc + left], LVF(rgbgreen[rr * ts + cc]) * coutscalev);
                        }

#endif

                        for (; cc < cc1 - 16; cc++) {
                            green[row][cc + left] = outputScale * rgbgreen[rr * ts + cc];
                        }
                    }

                    progresscounter++;

                    if(progresscounter % 32 == 0) {
#ifdef _OPENMP
                        #pragma omp critical (amazeprogress)
#endif
                        {
                            progress += 32.0 * SQR(ts - 32) / (height * width);
                            progress = std::min(progress, 1.0);
                            setProgCancel(progress);
                        }
                    }
                }
            }  //end of main loop
        }
        // clean up
        if (buffer) {
            free(buffer);
        }
    }
    if(border < 4 && rc == RP_NO_ERROR) {
        rc = bayerborder_demosaic(width, height, 3, rawData, red, green, blue, cfarray);
    }

    setProgCancel(1.0);

    return rc;
}
